Chloroplast Vector Systems for Biotechnology Applications

Verma, Deepika; Daniell, Henry

doi:10.1104/pp.107.106690

Cited by 247 publications

(242 citation statements)

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“…Plastid transgenic lines also lack gene silencing (DeCosa et al, 2001;Lee et al, 2003), position effect due to site specific transgene integration and pleiotropic effects due to subcellular compartmentalization of transgene products (Lee et al, 2003;Daniell et al, 2001;Leelavathi et al, 2003); concerns of transgene silencing, position effect and pleiotropic effects are often encountered in nuclear genetic engineering. Therefore, transgenes have been integrated into plastid genomes to confer valuable agronomic traits, including herbicide resistance (Daniell et al, 1998), insect resistance (McBride et al, 1995;DeCosa et al, 2001), disease resistance (DeGray et al, 2001), drought tolerance (Lee et al, 2003), salt tolerance (Kumar et al, 2004), phytoremediation (Ruiz et al, 2003;Hussein et al, 2007) or expression of various therapeutic proteins or biomaterials (Verma and Daniell, 2007;Kamarajugadda and Daniell, 2006;Daniell et al, 2005). However, soybean is the only legume that has been transformed via the plastid genome so far (Dufoumantel et al, 2004(Dufoumantel et al, , 2005 and more genome sequence information is needed to facilitate plastid genetic engineering in other economically important legumes.…”

Section: Introductionmentioning

confidence: 99%

Complete plastid genome sequence of the chickpea (Cicer arietinum) and the phylogenetic distribution of rps12 and clpP intron losses among legumes (Leguminosae)

Jansen

Wojciechowski

Elumalai

et al. 2008

Molecular Phylogenetics and Evolution

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Chickpea (Cicer arietinum, Leguminosae), an important grain legume, is widely used for food and fodder throughout the world. We sequenced the complete plastid genome of chickpea, which is 125,319 bp in size, and contains only one copy of the inverted repeat (IR). The genome encodes 108 genes, including 4 rRNAs, 29 tRNAs, and 75 proteins. The genes rps16, infA, and ycf4 are absent in the chickpea plastid genome, and ndhB has an internal stop codon in the 5′exon, similar to other legumes. Two genes have lost their introns, one in the 3′exon of the transpliced gene rps12, and the one between exons 1 and 2 of clpP; this represents the first documented case of the loss of introns from both of these genes in the same plastid genome. An extensive phylogenetic survey of these intron losses was performed on 302 taxa across legumes and the related family Polygalaceae. The clpP intron has been lost exclusively in taxa from the temperate "IR-lacking clade" (IRLC), whereas the rps12 intron has been lost in most members of the IRLC (with the exception of Wisteria, Callerya, Afgekia, and certain species of Millettia, which represent the earliest diverging lineages of this clade), and in the tribe Desmodieae, which is closely related to the tribes Phaseoleae and Psoraleeae. Data provided here suggest that the loss of the rps12 intron occurred after the loss of the IR. The two new genomic changes identified in the present study provide additional support of the monophyly of the IR-loss clade, and resolution of the pattern of the earliest-branching lineages in this clade. The availability of the complete chickpea plastid genome sequence also provides valuable information on intergenic spacer regions among legumes and endogenous regulatory sequences for plastid genetic engineering.

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Section: Introductionmentioning

confidence: 99%

Complete plastid genome sequence of the chickpea (Cicer arietinum) and the phylogenetic distribution of rps12 and clpP intron losses among legumes (Leguminosae)

Jansen

Wojciechowski

Elumalai

et al. 2008

Molecular Phylogenetics and Evolution

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200

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“…Gene abbreviations can be found in Table I Staub and Maliga, 1994a;Eibl et al, 1999). However, researchers still routinely used regulatory elements including promoters and untranslated regions with homology to sequences within the host plastome (Verma and Daniell, 2007), often because these were the only sequences readily available for use. While our experiments were in progress, the magnitude of the recombination issue was realized by several laboratories (Huang et al, 2002;Rogalski et al, 2006;Zhou et al, 2008;Gray et al, 2009), including our own.…”

Section: Discussionmentioning

confidence: 99%

High Levels of Bioplastic Are Produced in Fertile Transplastomic Tobacco Plants Engineered with a Synthetic Operon for the Production of Polyhydroxybutyrate

et al. 2011

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An optimized genetic construct for plastid transformation of tobacco (Nicotiana tabacum) for the production of the renewable, biodegradable plastic polyhydroxybutyrate (PHB) was designed using an operon extension strategy. Bacterial genes encoding the PHB pathway enzymes were selected for use in this construct based on their similarity to the codon usage and GC content of the tobacco plastome. Regulatory elements with limited homology to the host plastome yet known to yield high levels of plastidial recombinant protein production were used to enhance the expression of the transgenes. A partial transcriptional unit, containing genes of the PHB pathway and a selectable marker gene encoding spectinomycin resistance, was flanked at the 5# end by the host plant's psbA coding sequence and at the 3# end by the host plant's 3# psbA untranslated region. This design allowed insertion of the transgenes into the plastome as an extension of the psbA operon, rendering the addition of a promoter to drive the expression of the transgenes unnecessary. Transformation of the optimized construct into tobacco and subsequent spectinomycin selection of transgenic plants yielded T0 plants that were capable of producing up to 18.8% dry weight PHB in samples of leaf tissue. These plants were fertile and produced viable seed. T1 plants producing up to 17.3% dry weight PHB in samples of leaf tissue and 8.8% dry weight PHB in the total biomass of the plant were also isolated.

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“…Although several selection markers and protocols have been developed, those based on aadA (encoding aminoglycoside 3″-adenylyltransferase, EC 2.7.7.47, and conferring spectinomycin and streptomycin resistance to bacteria by detoxification) are the most frequent ones (Table 1), most likely because they require low expression levels to confer phenotypic resistance. Detailed description and historical overview of the used vectors including promoters, effective selection markers, reporter genes, their insertion, and eventual removal are provided by recent reviews (Maliga 2003(Maliga , 2004Koop et al 2007;Verma and Daniell 2007;Ruhlman et al 2010;Day and Goldschmidt-Clermont 2011;Maliga and Bock 2011;Ahmad and Mukhtar 2013;Hanson et al 2013;Vafaee et al 2014).…”

Section: Genetic Transformation Of Plastidsmentioning

confidence: 99%

“…These include (1) absence of gene silencing, epigenetic, and/or position effects, which eliminates the high variation in gene expression and thus in protein accumulation levels among independent transgenic lines; (2) high protein expression levels due to very high plastid DNA copy number per chloroplasts/cells/organ resulting in the accumulation of large amounts of the transgene's product in the chloroplast/ cell/organ; (3) possibility of multigene engineering (including cDNAs instead of full genes) through the use of transgene stacking in operons in a single transformation event; and (4) almost complete absence of pleiotropic effects due to subcellular compartmentalization of the transgene products (e.g., Staub et al 2000;Bock 2001Bock , 2013De Cosa et al 2001;Daniell et al 2002;Quesada-Vargas et al 2005;Verma and Daniell 2007;Oey et al 2009;Ruhlman et al 2010;Meyers et al 2010). From the biosafety point of view, the plastid technology (5) significantly increases transgene containment because plastids are maternally inherited in most crops, and therefore, the transgenes are not transmitted by pollen (Section 5) and outcrossing with weeds and other plants is not possible (Daniell et al 1998Daniell 2002;Hagemann 2004Hagemann , 2010.…”

Section: Genetic Transformation Of Plastidsmentioning

confidence: 99%

“…In addition to carbohydrates, plastids are also involved in the synthesis and/or the storage of amino acids, lipids and fatty acids, starch, oil, and some secondary metabolites including carotenoids, terpenoids, alkaloids, lignanes, essential vitamins such as vitamin A, B1, B2, B3, B9, E, and K (Fitzpatrick et al 2012) or polyphenolic compounds like condensed tannins (Brillouet et al 2013) (reviewed in Verma and Daniell 2007;Solymosi and Keresztes 2012).…”

Section: Genetic Transformation Of Plastidsmentioning

confidence: 99%

See 1 more Smart Citation

Transplastomic plants for innovations in agriculture. A review

Wani

Sah

Sági

et al. 2015

Agron. Sustain. Dev.

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Food production has to be significantly increased in order to feed the fast growing global population estimated to be 9.1 billion by 2050. The Green Revolution and the development of advanced plant breeding tools have led to a significant increase in agricultural production since the 1960s. However, hundreds of millions of humans are still undernourished, while the area of total arable land is close to its maximum utilization and may even decrease due to climate change, urbanization, and pollution. All these issues necessitate a second Green Revolution, in which biotechnological engineering of economically and nutritionally important traits should be critically and carefully considered. Since the early 1990s, possible applications of plastid transformation in higher plants have been constantly developed. These represent viable alternatives to existing nuclear transgenic technologies, especially due to the better transgene containment of transplastomic plants. Here, we present an overview of plastid engineering techniques and their applications to improve crop quality and productivity under adverse growth conditions. These applications include (1) transplastomic plants producing insecticidal, antibacterial, and antifungal compounds. These plants are therefore resistant to pests and require less pesticides. (2) Transplastomic plants resistant to cold, drought, salt, chemical, and oxidative stress. Some pollution tolerant plants could even be used for phytoremediation. (3) Transplastomic plants having higher productivity as a result of improved photosynthesis. (4) Transplastomic plants with enhanced mineral, micronutrient, and macronutrient contents. We also evaluate field trials, biosafety issues, and public concerns on transplastomic plants. Nevertheless, the transplastomic technology is still unavailable for most staple crops, including cereals. Transplastomic plants have not been commercialized so far, but if this crop limitation were overcome, they could contribute to sustainable development in agriculture.

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Chloroplast Vector Systems for Biotechnology Applications

Cited by 247 publications

References 115 publications

Complete plastid genome sequence of the chickpea (Cicer arietinum) and the phylogenetic distribution of rps12 and clpP intron losses among legumes (Leguminosae)

Complete plastid genome sequence of the chickpea (Cicer arietinum) and the phylogenetic distribution of rps12 and clpP intron losses among legumes (Leguminosae)

High Levels of Bioplastic Are Produced in Fertile Transplastomic Tobacco Plants Engineered with a Synthetic Operon for the Production of Polyhydroxybutyrate

Transplastomic plants for innovations in agriculture. A review

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